During the fellowship period, the project achieved significant milestones across theoretical development, computational modelling and experimental interpretation. The key technical and scientific achievements include
1. Machine Learning for Nuclear Physics: A robust hybrid machine-learning framework was developed to predict nuclear charge radii. This approach combined numerical regression for high accuracy with symbolic regression to extract simplified, interpretable mathematical expressions.
2. Quantum Simulation: The project demonstrated a numerical simulation using the ADAPT-SSVQE algorithm to obtain low-lying states of nuclear systems in a single optimization run. This method was successfully applied to map a two-nucleon system to qubits, perfectly matching exact diagnoalization benchmarks.
3. Isomer Analysis and Predictions: Theoretical analysis directly supported the first lifetime measurement of 9- state in the odd-odd 92Nb. The applied shell model analysis successfully uncovered the curical role of core-excitations in dictating the origin and evolution of these negative-parity states. Besides this, large scale shell model calculations successfully explained complex decay schemes, missing transitions and pair breakups in isotopes such as 201Po, 202Po. Furthermore, the project established direct correlations between nuclear sixe and electric monopole transitions in calcium, argon and titanium isotopes using the interacting boson model.
4. Interdisciplinary Applications: A detailed shell model analysis quantified the dominant role of neutron-proton interactions in 93Mo, an important candidate for nuclear excitations by electronic capture. The study revealed that this favorable structure stems from subtle interaction systematics that do not persist across neighboring isotones.